Insulated cap

ABSTRACT

Container assemblies including an insulated cap for sealing the mouth of the container, the insulated cap including an outer shell, an insulation block defining a plurality of elongate voids disposed at least partially within the outer shell, a securing element configured to secure the cap to the container, and a sealing member configured to form a seal between the insulated cap and the container when the insulated cap is secured to the container by the securing element.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the benefit under 35 U.S.C. § 119(e) of the priority of U.S. Provisional Patent Application Ser. No. 62/155,356, filed Apr. 30, 2015, which is hereby incorporated by reference in its entirety.

TECHNICAL FIELD

This disclosure relates to thermally insulated containers for liquids, and more specifically to thermally insulated caps for such thermally insulated containers.

INTRODUCTION

When a need exists to store or transport a substance, and it is furthermore desirable to keep that substance at temperature that is either higher or lower than ambient temperature, the solution is typically an insulated container. Insulated containers are available in a vast number of configurations depending upon the substance to be transported and the temperatures to be maintained, from the thermal bags used to deliver hot pizzas to the cryogenic storage dewars used to hold cryogens such as liquefied gases.

Of particular utility are beverage containers, such as water bottles or sports bottles, that are typically used to contain beverages that are either colder (such as ice water) or hotter (such as coffee) than ambient temperatures. To maintain such beverages at their desired temperature for a desired amount of time, such containers typically contain insulating structures and/or materials.

SUMMARY

The present disclosure is directed to insulated caps, assemblies of containers and insulated caps, and methods of manufacturing insulated caps.

In one aspect, the disclosure is directed to an insulated cap for sealing a mouth of a container, including an outer shell, an insulation block disposed at least partially within the outer shell that defines a plurality of elongate voids, a securing element configured to secure the cap to the container, and a sealing member configured to form a seal between the insulated cap and the container when the insulated cap is secured to the container by the securing element.

In another aspect, the disclosure is directed to a container assembly that includes an insulated beverage container and an insulated cap. The insulated beverage container may include an inner bottle disposed within an outer bottle defining an air-tight space between the inner bottle and the outer bottle and continuously surrounding the inner bottle, a neck portion that defines a mouth of the container, and a securing element disposed on or near the neck portion. the insulated cap may include an outer shell, an insulation block disposed at least partially within the outer shell defining a plurality of substantially parallel elongate voids, a securing element configured to secure the insulated cap to the securing element of the container, and a sealing member configured to form a seal between the insulated cap and the insulated beverage container when the insulated cap is secured to the container by the interaction of the securing elements.

In another aspect, the disclosure is directed to a method of making an insulating cap, including forming an insulation block having an upper surface and a lower surface and defining a plurality of voids in the upper surface, forming an outer shell to form an outer surface of the insulating cap, and coupling the insulation block with the outer shell so the outer shell caps each of the plurality of cavities in the insulation block.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a partially exploded view of an illustrative container assembly of the present disclosure that includes an insulated cap.

FIG. 2 is a view of the underside of the insulated cap of FIG. 1.

FIG. 3 is a view of an alternative and illustrative insulated cap of the present disclosure.

FIG. 4 is a cross-section view of the insulated cap of FIG. 1.

FIG. 5 is a partial cut-away view of the insulated cap of FIG. 1.

FIG. 6 is an exploded view of the insulated cap of FIG. 1.

FIG. 7 is a flowchart of an illustrative method of making an insulated cap to the present disclosure.

DESCRIPTION

The present disclosure may illustrate and describe a number of insulated caps in the present drawings and specification. Unless otherwise specified, the insulated cap and/or its various components may, but are not required to, contain at least one of the structure, components, functionality, and/or variations described, illustrated, and/or incorporated herein. Furthermore, the process steps, structures, components, functionalities, and/or variations described, illustrated, and/or incorporated herein in connection with the present teachings may, but are not required to, be included in other similar insulated caps. The following description is merely exemplary and is in no way intended to limit the disclosure, its application, or uses. Additionally, the advantages provided by the embodiments, as described below, are illustrative and not all embodiments provide the same advantages or the same degree of advantages.

FIG. 1 depicts an illustrative insulated container assembly 10 that includes an insulated container 12 and an insulated cap 14 that is complementary to the insulated container 12. The insulated cap 14 and insulated container 12 are depicted in a partially exploded view for clarity. The insulated cap 14 may be configured to be removably attachable to the associated thermally insulated container 12. The underside of insulated cap 14 is shown in FIG. 2.

The insulated container 12 may be configured to retain a desired substance, and particular may be configured to retain the desired substance at a temperature that is either higher or lower than an ambient temperature. In one aspect of the disclosure, the insulated container 12 is configured to be used as a beverage container, and may correspond to or resemble a bottle, jug, growler, vessel, carafe, or similar beverage container. Insulated container 12 may be fashioned from any material having the properties for a beverage container, such as a stainless steel or a plastic formulation. insulated container 12 may incorporate any of a variety of insulating materials, or combination of insulating materials, so as to limit the transfer of heat through the walls the container. In one aspect of the disclosure, the insulated container 12 may a double-walled construction, with the intervening space between the walls being substantially evacuated, so that the container is a vacuum-insulated container.

Insulated container 12 may include any suitable container configured to portably contain liquids. For example, insulated container 12 may include a bottle, jug, growler, vessel, carafe, or the like. The insulated container 12 may include a stainless steel vessel. In one aspect of the disclosure the container is fashioned from stainless steel, incorporates a double-walled construction, and is vacuum-insulated. Examples of appropriate vacuum-insulated stainless steel beverage containers for the purposes of the present disclosure may be commercially available from HYDRO FLASK (Bend, Oreg.).

The insulated container 12 may include a mouth portion 16 that provides access to an interior 18 of the insulated container 12. In some aspects, the insulated container 12 may include a mouth portion 16 that forms an opening at the distal portion of a neck 20 of the insulated container 12. The upper portion of the insulated container 12 may be defined as that portion of the insulated container 12 that includes the neck 20 and mouth portion 16 of the insulated container, consistent with the conventional and common usage when describing a container for liquids.

As may be more clearly shown in FIG. 2, the portion of the insulated cap 14 that may be configured to make contact with the mouth portion 16 and to face the interior 18 of the insulated container 12 may be referred to as the interior portion 22, or inner portion, or lower portion of the insulated cap 14, without limitation. Similarly, the surface of the insulated cap 14 that faces the interior 18 of the insulated container 12 may be referred to as an inner surface 24 of the insulated cap 14.

The portion of the insulated cap 14 that may be disposed opposite the interior portion 22 may be referred to as the exterior portion 26, the upper portion, or the outer portion of the insulated cap 16, without limitation. Similarly, the surface of the insulated cap 14 disposed opposite the inner surface 24 of the insulated cap may be referred to as the outer surface 27 of the insulated cap 14, the upper surface of the insulated cap, or the exterior surface of the insulated cap, without limitation.

The insulated cap 14 (which may alternatively be referred to as a lid) may include one or more suitable structures and components configured so as to provide a sealing closure for mouth 16 of insulated container 12. The insulated cap 14 may a first securing element 30 that is configured to secure the insulated cap 14 to the insulated container 12, such that when the insulated cap 14 is secured by securing element 30, the container assembly 10 is substantially airtight, and the contents of the container assembly 10 are substantially not prone to leaking during routine handling and/or transport. The first securing element 30 may be configured to be complementary to, and to cooperate with, a second securing element 32 disposed on or coupled to the insulated container 12.

For example, and with reference to FIG. 1, the insulated cap 14 may include a first securing element 30 that corresponds to a threading 34 that is complementary to a second securing element 32 that may include a threading 36 disposed on or adjacent to the mouth portion 16 or neck 20 of the insulated container 12. That is, threading 34 of the insulated cap 14 may be configured to mate with threading 36 of the insulated container 12, so that the insulated cap 14 may be secured to the neck 20 and thereby secured to and against mouth portion 16.

As shown in FIG. 1, for those aspects of the disclosure where the first and second securing elements may include complementary threading, the threading 36 on the insulated container 12 may be disposed on an outer surface 38 of neck portion 26 of the insulated container 12, and the corresponding complementary threading 34 may be disposed on an inner surface 40 of a circumferential sidewall 42 of the insulated cap 14, so that threading 34 and threading 36 may positively interact to secure the insulated cap 14 to the insulated container 12.

However, it should be appreciated that in an alternative aspect of the disclosure, the insulated container 12 may include threading 36 disposed on an inner surface of the neck 20 of the insulated container 12. In this instance, as shown in FIG. 3, the complementary cap threading 34 may be disposed on a projecting interior portion 22 of the insulating cap 14 that may be configured to be inserted at least partially into the neck 20 of the insulated container 12, such that threading 34 and threading 36 may positively interact to secure the insulated cap 14 to the insulated container 12.

Although insulated beverage containers having threaded couplings to their lids described herein, it should be readily apparent that a variety of additional and/or alternative configurations and conformations of securing elements may be utilized in the container assemblies of the present disclosure, and any alternative securing element or pair of securing elements that serve to secures the insulated cap 14 against the container 12 and to create a substantially airtight seal may be an appropriate securing element or elements for the purposes of this disclosure. For example, the insulated cap 14 may be retained by a securing element that includes a swing-top closure, where the insulated cap 14 may be retained by a wire bail configured so that in a first position the insulated cap 14 is retained in place against the mouth portion 16 of the insulated container 14, and a second position where the insulated cap 14 is released from contact with the insulated container 12, but the cap 14 remains connected to the container 12 the wire bail. The wire bail may be configured so that the wire bail may be manually from the first position to the second position, thereby opening the container assembly

The insulated cap 14 (also referred to as a lid) may include any suitable structures and components configured to provide an insulated, releasable sealing closure for mouth 16 of insulated container 12. As shown in FIGS. 4-6, an illustrative insulated cap 14 according to the present disclosure may include an outer shell 44, an insulation block 46, and a sealing member 48. Additionally, or in the alternative, the insulated cap 14 may include a handle or carrying strap 50.

Outer shell 44 may include any suitable structure configured to provide an outer cap, shell, or housing for insulated cap 14, and may further include a grippable and/or manipulable surface configured to assist in attaching and/or detaching the insulated cap 14 from the insulated container 12. The outer shell 44 may incorporate one or more contours and/or portions or regions of texture. Alternatively, or in addition, the outer shell 44 may be molded or inscribed to provide an aesthetic, instructional, or functional interface for a user of the insulated container assembly 10. Outer shell 44 may include any suitable material having sufficient structural strength and rigidity to form the outer shell. For example, outer shell 44 may include a plastic, such as a thermoplastic, or a thermosetting polymer. In one aspect of the disclosure, the outer shell 44 incorporates a thermoplastic that is a polypropylene polymer.

In addition to structures and features disposed on an exterior surface 52 of outer shell 44, the outer shell of insulated cap 14 may also include one or more features on interior surface that are configured to interact with one or more features of the insulated cap. For example, outer shell 44 may define apertures or through-holes that may be configured to facilitate the attachment of a carrying strap 50, and/or contours and disposed on or formed in an inner surface 54 of the outer shell 44 that are configured to interface with insulation block 46.

Insulation block 46 may be mated with, attached to, or unitary with the inner surface 54 of outer shell 44, such that outer shell 44 substantially covers both the upper and lateral surfaces of the insulation block 46. Insulation block 46 may include any suitable insulating material or insulating structure configured to enhance the thermal insulating properties of the insulating cap 14. That is, to reduce the rate of heat transfer between the lower or inner surface 24 of the insulated cap and the upper or outer surface 28 of the insulated cap 14. In other words, insulation block 46 may be configured to function as a thermal barrier to heat transfer between the interior and the exterior of the insulated container 12.

Insulation block 46 may incorporate any suitable material, structure, or device configured to reduce heat transfer between the upper and lower surfaces (or the outer and inner surfaces) of the insulation block 46. For example, for example, insulation block 46 may include one or more materials that have inherently low heat transfer characteristics. In addition to having advantageous thermal properties, the materials making up insulation block 46 may be selected based upon their mechanical properties, such as being easy to form and/or machine. For example, insulation block 46 may comprise one or more plastics, such as thermosetting polymers, thermoplastics, or other polymer formulations. The insulation block 46 may include one or more plastics that may be the same or different than the plastics used for forming outer shell 44. In a selected aspect of the disclosure, the insulation block 46 may be formed from polypropylene polymer.

In addition to the incorporation of an insulating material, the insulation block 46 may be formed into a structure or shape that itself enhances the thermal insulating properties of the insulation block 46. For example, insulation block 12 may include a plurality of internal voids or apertures 56 configured so that the spaces formed by the voids 56 decrease the thermal transfer due to conduction through the material of the insulation block 46. The voids 56 may take the form of a plurality of closed cells, a of open cells, or a combination thereof. The insulation block 46 may be configured so one or more of voids 56 are filled with air, and the resulting plurality of air-spaces the insulating qualities of the insulation block 46. Alternatively, or in addition, one or of voids 56 may be filled with a gas, such as for example nitrogen, carbon dioxide, among others. In yet another aspect of the insulation block 46, one or more of voids 56 may be evacuated, so that the resulting evacuated spaces enhance the thermal insulating properties of insulation block 46.

Any appropriate number and arrangement of voids or apertures 56 may be formed in insulation block 46. In one aspect of the disclosure, the voids or apertures 56 are defined so that they are elongate voids. That is, the void extends further in one dimension than in any other dimension. Where one or more voids 56 are elongate voids, the voids may be deemed to possess a longitudinal axis.

The insulation block 46 may incorporate a plurality of elongate voids 56 that are formed so that the longitudinal axes of each of the elongate voids are substantially parallel to one another. In other words, the elongate voids 56 may be disposed so that they are substantially aligned with one another. The elongate voids 56 may be formed in insulation block 46 so that their longitudinal axes extend vertically, that is, the longitudinal axes extend between the upper and exterior portion 26 of the insulated cap 14 and the lower or interior portion 22 of the insulated cap 14.

The elongate voids may be formed in any shape or geometry that may be suitable, and that may enhance the thermal insulation of the insulated cap 14. In a selected aspect of the disclosure, each of the elongate voids has a polygonal cross-section, where the cross-section is taken at right angles to the longitudinal axis of the void, such that each includes an elongate polygonal columnar void. For example, each of the elongate voids may have a cross-section that defines a hexagon. Where the elongate voids have a hexagonal cross-section, it may be advantageous for the hexagonal voids to be formed in a close-packed array, as shown in FIG. 5, thereby forming a honeycomb pattern. This construction may minimize the amount of material needed to form the insulation block 46, as well is reducing the loss of heat through the insulation block 46 through direct conduction.

Although the voids formed in the insulation block 46 may be completely in one aspect of the disclosure it may be advantageous to form the elongate voids 56 by forming a plurality of open-ended apertures in the upper face 58 of insulation block 46. this way, placing the insulation block 46 within the outer shell 44 serves to cap or seal apertures, as shown most clearly in FIGS. 4 and 5.

Insulation block 46 may be formed from any suitably non-toxic material that is also substantially taste-neutral. In other words, although some materials may impart a flavor to liquids they contact, a taste-neutral material does not, or does so to a much lower degree. Where insulation block 46 is formed from a non-toxic and taste-neutral material, the lower or inner surface of the insulation block 46 may also serve as the lower or inner face of the insulated cap 14.

Alternatively, the insulated cap 14 may further include an inner liner 62 configured to substantially isolate the interior volume of the insulated container 12 from the insulation block 46 when the insulated cap 14 is coupled to the insulated container 12, as shown in FIGS. 4 and 6. The inner liner 62 may also be non-toxic and substantially taste-neutral. Suitable inner liners 62 may be formed from, for example, stainless steel, or silicone, among others.

Where insulated cap 14 includes an inner liner 62, the inner liner may include a continuous capping structure configured to partially encase the insulation block 46, as shown in FIG. 4. In one aspect of the disclosure, the inner liner 62 may include a cap or cup that interfaces with insulation block 46 and/or outer shell 22 at an upper end of the liner 62, thereby forming a narrow annular channel into which the walls of the neck 20 of insulated container 12 may be inserted. In this way, the interior of the insulated container 12, and therefore the contents of insulated container 12, is exposed only to the inner liner 62, while the exterior of the insulated container 12 (e.g., threading 36) may contact outer shell 44 and/or insulation block 46.

The isolation of the insulation block 46 and inner shell 44 from the interior 18 of insulated container 12 may be further facilitated by the presence of sealing member 48. Sealing member 48 may include any material or structure that creates or enhances an air-tight seal between the insulated cap 14 and insulated container 12, such as a seal, a ring, a gasket, or O-ring. Although a variety of suitable shapes may be useful as a member, in one aspect of the disclosure the suitable sealing member 48 may include a resilient O-ring, which may incorporate a tubular ring or solid ring having a circular cross section. The O-ring may include a silicone rubber.

The insulated cap 14 may further include a handle that is configured to facilitate carrying the insulated container assembly 10. Although any type of handle may be used to carry the insulated container assembly, it may be particularly convenient to employ a handle that includes a loop or carrying strap 50, as shown in FIGS. 1-6. Carrying strap 50 may be coupled to the insulated cap 14 with a pivotable or a non-pivotable connection, and may include any suitable material or strap configuration adequate to support the weight of the assembled container assembly 10 when filled with a liquid. In one aspect of the disclosure, carrying strap 50 may include a flat strap. Carrying strap 50 may include a flexible, compliant, and/or resilient material, such as for example a flexible plastic, rubber, or silicone rubber material. The carrying strap 50 may be a single ply of material, or may incorporate one or more layers of material bound in a stack. In one aspect of the disclosure, carrying strap 50 is pivotally connected to the outer shell 44 of the insulated cap 14, and optionally further connected to the insulation block 46 within the outer shell 44, via two pins 66. Pins 66 may be attached to the insulated cap 14 by any suitable method, such as being press-fit into appropriate apertures formed in the outer shell 44. Such apertures may include a raised boss or protrusion. Alternatively, or in addition, pins 66 may be fixed by being overmolded during manufacture of the insulated cap 14. The pins 66 may include any suitable material, such as rigid or resilient plastic or rubber, or stainless steel.

Carrying strap 50 may be attached relatively permanently, or may be configured so that it can be removed and/or replaced, either to repair the carrying strap or to change the colors or appearance of the container assembly. The outer shell 44 and/or pins 66 may include contours or other features that may function as detent mechanisms to releasably retain strap 50 in a desired orientation with respect to insulated cap 14.

The insulated caps of the present disclosure may be manufactured as set out in flowchart 70 of FIG. 7, which includes forming an insulation block that defines a plurality voids formed in its upper surface, at 72; forming an outer shell configured to form an surface of an insulating cap, at 74; and coupling the insulation block with the outer shell that the outer shell caps the plurality of voids in the insulation block, at 76. The insulated caps 14 of the disclosure may be prepared via any suitable manufacturing method, including but not limited to spin-welding and/or over-molding processes.

Claim Concepts and Selected Embodiments:

This section describes additional aspects and features of insulated ca[s, presented without limitation as a series of paragraphs, some or all of which may be alphanumerically designated for clarity and efficiency. Each of these paragraphs can be combined with one or more other paragraphs, and/or with disclosure from elsewhere in this application, in any suitable manner. Some of the paragraphs below expressly refer to and further limit other paragraphs, providing without limitation examples of some of the suitable combinations.

-   A1. An insulated cap for sealing a mouth of a container, comprising:

an outer shell;

an insulation block disposed at least partially within the outer shell; wherein the insulation block defines a plurality of elongate voids;

a securing element, configured to secure the cap to the container; and

a sealing member configured to form a seal between the insulated cap and the container when the insulated cap is secured to the container by the securing element.

-   A2. The insulated cap of paragraph A1, wherein each of the plurality     of elongate voids has a longitudinal axis, and the longitudinal axes     of the plurality of elongate voids are substantially parallel. -   A3. The insulated cap of paragraph A1, wherein each of the plurality     of elongate voids has a longitudinal axis, and the longitudinal axes     of the plurality of elongate voids are oriented substantially     vertically within the insulated cap. -   A4. The insulated cap of paragraph A1, wherein each of the plurality     of elongate voids has a hexagonal cross-section. -   A5. The insulated cap of paragraph A1, further comprising a carrying     strap that is pivotally attached to the insulated cap. -   A6. The insulated cap of paragraph A1, wherein the securing element     includes threading that is configured to interact and mate with a     complementary threading on the container. -   A7. The insulated cap of paragraph A6, wherein the threading of the     insulated cap is disposed on an inner surface of the insulated cap,     and is configured to interact and mate with a complementary     threading on an outer surface of the container. -   A8. The insulated cap of paragraph A6, wherein the threading of the     insulated cap is configured to interact and mate with a     complementary threading on inner surface of a neck of the container. -   A9. The insulated cap of paragraph A1, further comprising a     taste-neutral cap liner configured such that when the insulated cap     is secured to the container by the securing element the cap liner is     exposed to the contents of the container -   B1. A container assembly, comprising: -   an insulated beverage container; -   wherein the insulated beverage container includes an inner bottle     disposed within an outer bottle such that an air-tight space exists     between and defined by the inner bottle and the outer bottle and the     air-tight space continuously surrounds the inner bottle, a neck     portion that defines a mouth of the container, and a securing     element disposed on or near the neck portion; and -   an insulated cap; -   wherein the insulated cap includes an outer shell, an insulation     block disposed at least partially within the outer shell that     defines a plurality of substantially parallel elongate voids, a     securing element configured to secure the insulated cap to the     securing element of the container, and a sealing member configured     to form a seal between the insulated cap and the insulated beverage     container when the insulated cap is secured to the container by the     interaction of the securing elements. -   B2. The container assembly of paragraph B1, wherein each of the     plurality of elongate voids has a longitudinal axis, and the     longitudinal axes of the plurality of elongate voids are oriented     substantially vertically within the insulated cap. -   B3. The container assembly of paragraph B1, wherein each of the     plurality of elongate voids has a hexagonal cross-section, and the     elongate voids are disposed in a honeycomb arrangement. -   B4. The container assembly of paragraph B1, wherein the securing     elements of the insulated cap and the insulated beverage container     are complementary portions of threading. -   B5. The container assembly of paragraph B4, wherein the threading     portion of the insulated beverage container is disposed on an     exterior surface of a neck of the beverage container, and the     threading portion of the insulated cap is disposed on an inner     surface of a circumferential sidewall of the insulated cap. -   B6. The container assembly of paragraph B4, wherein sealing member     is an O-ring that is configured to form a seal between the insulated     cap and the mouth of the container when the insulated cap is secured     to the container by the interaction of the complementary portions of     threading. -   C1. A method of making an insulating cap, comprising: -   forming an insulation block, wherein the insulation block has an     upper surface and a lower surface and defines a plurality of voids     formed in the upper surface; -   forming an outer shell configured to form an outer surface of the     insulating cap; coupling the insulation block with the outer shell     such that the outer shell caps each of the plurality of cavities in     the insulation block. -   C2. The method of paragraph C1, further comprising pivotally     coupling a carrying strap to the outer shell. -   C3. The method of paragraph C1, wherein forming the insulation block     includes defining a plurality of voids that are vertically elongated     within the insulation block -   C4. The method of paragraph C1, wherein forming the insulation block     includes defining a plurality of voids having hexagonal     cross-sections within the insulation block. -   C5. The method of paragraph C1, further comprising forming a     securing element in the insulated cap, where the securing element     includes threading.     C6. The method of paragraph C1, further comprising adding a sealing     member that is an O-ring to the insulated cap.

CONCLUSION

The disclosure set forth above may encompass multiple distinct inventions with independent utility. Although each of these inventions has been disclosed in its form(s), the specific embodiments thereof as disclosed and illustrated herein are not to considered in a limiting sense, because numerous variations are possible. To the extent that section headings are used within this disclosure, such headings are for organizational purposes only. The subject matter of this disclosure includes all novel nonobvious combinations and subcombinations of the various elements, features, functions, and/or properties disclosed herein. The claim concepts particularly point out certain combinations and subcombinations regarded as novel and nonobvious. Other combinations and subcombinations of features, functions, elements, and/or properties may be claimed in applications claiming priority from this or a related application. Such claims, whether directed to a different example or to the same example, and whether broader, narrower, equal, or different in scope to the original claims, also are regarded included within the subject matter of the present disclosure. Furthermore, explicit reference is hereby made to all embodiments and examples shown in the drawings, whether or not described further herein. 

What is claimed is:
 1. An insulated cap for sealing a mouth of a container, comprising: an outer shell; an insulation block disposed at least partially within the outer shell; wherein the insulation block defines a plurality of elongate voids, each elongate void having an opening in an upper face of the insulation block, and each elongate void being otherwise enclosed by the insulation block, such that each elongate void is capped by the outer shell; a securing element, configured to secure the cap to the container; and a sealing member configured to form a seal between the insulated cap and the container when the insulated cap is secured to the container by the securing element.
 2. The insulated cap of claim 1, wherein each of the plurality of elongate voids has a longitudinal axis, and the longitudinal axes of the plurality of elongate voids are substantially parallel.
 3. The insulated cap of claim 1, wherein each of the plurality of elongate voids has a longitudinal axis, and the longitudinal axes of the plurality of elongate voids are oriented substantially vertically within the insulated cap.
 4. The insulated cap of claim 1, wherein each of the plurality of elongate voids has a hexagonal cross-section.
 5. The insulated cap of claim 1, wherein the securing element includes threading that is configured to interact and mate with a complementary threading on the container.
 6. The insulated cap of claim 5, wherein the threading of the insulated cap is disposed on an inner surface of the insulated cap, and is configured to interact and mate with a complementary threading on an outer surface of the container, further wherein the threading of the insulated cap is configured to interact and mate with a complementary threading on an inner surface of a neck of the container.
 7. The insulated cap of claim 1, further comprising a taste-neutral cap liner configured such that when the insulated cap is secured to the container by the securing element the cap liner is exposed to the contents of the container.
 8. A container assembly, comprising: an insulated beverage container; wherein the insulated beverage container includes an inner bottle disposed within an outer bottle such that an air-tight space exists between and defined by the inner bottle and the outer bottle and the air-tight space continuously surrounds the inner bottle, a neck portion that defines a mouth of the container, and a securing element disposed on or near the neck portion; and an insulated cap; wherein the insulated cap includes an outer shell, an insulation block disposed at least partially within the outer shell that defines a plurality of substantially parallel elongate voids, each elongate void having an opening in an upper face of the insulation block, and each elongate void being otherwise enclosed by the insulation block, such that each elongate void is capped by the outer shell, a securing element configured to secure the insulated cap to the securing element of the container, and a sealing member configured to form a seal between the insulated cap and the insulated beverage container when the insulated cap is secured to the container by the interaction of the securing elements.
 9. The container assembly of claim 8, wherein each of the plurality of elongate voids has a hexagonal cross-section and a longitudinal axis, and the longitudinal axes of the plurality of elongate hexagonal voids are oriented substantially vertically within the insulated cap in a honeycomb arrangement.
 10. The container assembly of claim 8, wherein the securing elements of the insulated cap and the insulated beverage container are complementary portions of threading.
 11. The container assembly of claim 10, wherein the threading portion of the insulated beverage container is disposed on an exterior surface of a neck of the beverage container, and the threading portion of the insulated cap is disposed on an inner surface of a circumferential sidewall of the insulated cap.
 12. The container assembly of claim 10, wherein the sealing member includes an O-ring that is configured to form a seal between the insulated cap and the mouth of the container when the insulated cap is secured to the container by the interaction of the complementary portions of threading.
 13. A method of making an insulating cap, comprising: forming an insulation block having, an upper surface and a lower surface, the insulation block defining a plurality of voids each having an opening in the upper surface and otherwise enclosed by the insulation block; forming an outer shell configured to form an outer surface of the insulating cap; coupling the insulation block with the outer shell such that the outer shell caps each of the openings of the plurality of voids in the insulation block.
 14. The method of claim 13, further comprising pivotally coupling a carrying strap to the outer shell.
 15. The method of claim 13, wherein forming the insulation block includes defining a plurality of vertically elongated voids having hexagonal cross-sections within the insulation block.
 16. The method of claim 13, further comprising forming a securing element in the insulated cap, where the securing element includes threading. 